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EASYPol Module 116
Using Marginal Abatement
Cost Curves to Realize the
Economic Appraisal of
Climate Smart Agriculture
Policy Options
by
Louis Bockel, FAO Policy Analyst, Pierre Sutter, Ophélie Touchemoulin,
Madeleine Jönsson, FAO Consultants, Policy Assistance Support Service, Policy
and Programme Development Support Division
Reviewed
by
Michael
MacLeod
and
Benjamin
Henderson,
FAO
Technical/Livestock Policy Officers, Livestock Information, Sector Analysis and
Policy Branch
FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS
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estimations of the impact of agriculture and forestry development projects on GHG emissions
and carbon sequestration, indicating its effects on the carbon balance. See EX-ACT website:
www.fao.org/tc/exact
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
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Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
The EX Ante Carbon-balance Tool
Table of contents
1 Summary __________________________________________________ 1
2 Introduction _______________________________________________ 2
3 The use of MACC within the agricultural sector: methodology and limits _ 3
3.1 Background of Marginal Abatement Cost Curves ________________________3
3.2 Understanding a Marginal Abatement Cost Curve _______________________4
3.2.1
The socially optimal quantity of pollution ___________________________________________________ 4
3.2.2
The MACC curve _____________________________________________________________________ 5
3.3 Using MACC as a planning tool in agriculture __________________________7
3.3.1
Relevance of the MACC approach to appraise low carbon options within a policy ___________________ 7
3.3.2
Methodology for a MACC assessment in the AFOLU sector ____________________________________ 8
3.3.3
Development of the MACC analysis: points to be aware of ____________________________________ 14
4 Concrete application of the MACC within the EX-ACT tool ____________ 21
4.1 Carbon balance appraisal with EX-ACT ______________________________21
4.2 Linking EX-ACT results with MACC design ____________________________22
4.3 Example of the Turkey National Climate Change Strategy _______________24
4.3.1
Selection of the low carbon options to appraise and calculation of the mitigation potential ____________ 24
4.3.2
Evaluation of the cost effectiveness and analysis of the MACC results ___________________________ 27
5 Conclusion ________________________________________________ 29
6 Readers’ Notes ____________________________________________ 30
6.1 Links to other related EASYPol modules _____________________________30
7 Futher Reading ____________________________________________ 30
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Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
The EX Ante Carbon-balance Tool
ABBREVIATIONS
AFOLU
Agriculture, Forestry, land Use
C
Carbon
CCC
The Committee on Climate Change
CO2e
CO2 equivalent
EX-ACT
EX-Ante Carbon balance Tool
GHG
Green House Gases
IRR
Internal Rate on Return
MACC
Marginal Abatement Cost Curve
MEC
Marginal External Cost
MPC
Marginal Private Cost
MSB
Marginal Social Benefit
MSC
Marginal Social Cost
NPV
Net Present Value
PES
Payement for Environnemental Services
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
The EX Ante Carbon-balance Tool
1
1
SUMMARY
The AFOLU sector (Agriculture, Forestry, Land Use) is directly linked with climate change issues, on
an environmental aspect as well as on an economical and social aspect (food security).
On the one hand, the sector directly contributes to climate change. Indeed, agriculture represents 14%
of the total worldwide GHG emissions, and deforestation accounts for 17% 1. The AFOLU sector is
thus responsible for one third of the GHG emissions in the world. Moreover, this sector is increasingly
vulnerable to climate changes and hence requires adaptation measures. On the other hand, it is
estimated that the mitigation potential of the AFOLU sector could reach up to 4.5-6 Gt CO2e/year in
2030 2. Many of the technical mitigation options are readily available 3 and could be deployed
immediately. Furthermore, estimates indicate that many of these options are of relatively low cost, or
generate significant co-benefits in the form of improved agricultural production systems, resilience and
other ecosystem services 4.
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Yet, while there is a wide range of technical solutions, it is not immediately apparent which options
deliver the most economically efficient reductions in GHG within agriculture. This is why
methodologies such as a Marginal Abatement Cost Curves (MACC) have been developed over these
past twenty years. MACC also enables the comparison of the cost-effectiveness of mitigation options
between different sectors (e.g. agriculture, power, transport, industry and domestic energy
consumption). MACC has become a useful tool for policy makers to prioritize mitigation options.
This paper aims at putting forward a methodology to use MAC-curves within the AFOLU sector. It
especially targets policy planners and policy makers. The agricultural sector, also called agriculture or
AFOLU, encompasses farm-based activities (crop production, livestock) as well as forestry and land
use. It does not include the downstream agro-industry sector.
The first part of these guidelines explains the methodology in order to assess the cost-effectiveness and
the mitigation potential of technical practices in agriculture. It also underlines the limits of the MACC
approach. The second part looks at a practical MACC analysis example, using the EX-ACT tool. The
outline of the paper is presented below.
1
UNFCCC, 2008.
IPCC, 2007; Smith and al, 2007.
3
Bellassen et al., 2010; Bernoux et al., 2006; Cerri et al., 2004, 2007; Henry et al., 2009.
4
Smith et al., 2008.
2
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Figure 1: Outline of the paper
1. MACC analysis: the theory
What is MACC and why is it useful
Chapter
2.3.1
2.1,
The methodology in 4 steps
Chapter 2.3.2
7 points to be aware of
Chapter 2.3.3
2.2
and
2. MACC analysis: the practice
with EX-ACT
Adapting
analysis
EX-ACT
to
a
MACC
Example with the Turkey National
Climate Change Strategy
2
Chapter 3.1 and 3.2
Chapter 3.3
INTRODUCTION
Objective: The objective of this paper is to provide
good practice guidance for the construction of
Marginal Abatement Cost Curves (MACC) in the AFOLU sector, in general and by using the EX-ACT
tool.
The purpose is not to set a fixed method that will not allow considering the specificities of different
contexts or countries. On the contrary, it is a general guideline provided to narrow down subjectivities
and provide a common understanding of important aspects to be taken into account while establishing a
MACC analysis in the agricultural sector.
Target audience: This
paper targets the national agriculture sector, forestry and food security policy
makers, institution-based, agency and donor decision-makers.
Required background:
In order to fully understand the content of this module the user must be
familiar with:
 Concepts of climate change mitigation and adaptation
 Concepts of land use planning and management
 Elements of project economic analysis
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Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
The EX Ante Carbon-balance Tool
Readers can follow links included in the text to other EASYPol modules or references 5. See also the
list of EASYPol links included at the end of this module.
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THE USE OF MACC WITHIN THE AGRICULTURAL SECTOR: METHODOLOGY AND LIMITS
3.1
Background of Marginal Abatement Cost Curves
Marginal Abatement Cost Curves (MACC) were first developed after the two oil price shocks, in the
1970’s. They aimed at reducing crude oil consumption, and later electricity consumption 6. The MACC
was then used for different purposes: assessment of abatement potential and costs of air pollutants 7 or
water availability 8. MACC began to be used in the agricultural sector in the years 2000, using
qualitative judgment 9 and more empirical methods. 10 11
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In recent years, MACC has become very popular with policy makers, especially with the McKinsey
and Company report (2008, 2009, 2010), analysing the global GHG abatement cost curves for different
sectors, including agriculture.
Policy-makers use MAC-curves in order to demonstrate how much abatement an economy can afford
and the area of focus, with respect to policies, to achieve the emission reductions.
The study of Climate Change in Agriculture – Impacts, adaptation and mitigation 12 has identified the
development of marginal abatement cost modelling as one of the five areas of research and policy
advocacy relevant for the OECD in relation to furthering the economics of climate change in
agriculture. 13
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EASYPol hyperlinks are shown in blue, as follows:
a) Resource packages are shown in underlined bold font
b) other EASYPol modules or complementary EASYPol materials are in bold underlined italics;
c) links to the glossary are in bold; and
d) external links are in italics.
6
Farugui et al. 1990, Jackson 1991.
7
Silverman 1985, Rentz et al. 1994.
8
Addams et al. 2009.
9
ECCP, 2001; Weiske, 2005-2006.
10
McCarl and Schneider, 2001, 2003; US-EPA, 2005, 2006; Weiske and Michel, 2007; Schneider et al., 2007, Smith et al.,
2007a,b, 2008; Pérez and Holm-Müller, 2005; De Cara et al., 2005; Deybe and Fallot, 2003.
11
Developing greenhouse gas marginal abatement cost curves for agricultural emissions from crops and soils in the UK,
M.MacLeod and al., Agricultural Systems, Volume 103, Issue 4, May 2010, Pages 198-209
http://onlinelibrary.wiley.com/doi/10.1111/j.1477-9552.2010.00268.x/pdf
12
OECD publishing.
13
Climate Change in Agriculture – Impacts, adaptation and mitigation, Anita Wreford, Dominic Moran and Neil Adger,
OECDpublishing, 2010
http://www.fao.org/fileadmin/user_upload/rome2007/docs/Climate%20Change%20and%20Agr.pdf
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3.2
Understanding a Marginal Abatement Cost Curve
3.2.1
The socially optimal quantity of pollution
To answer the question “how much pollution a society should allow?” the marginal benefit from an
additional unit of pollution has to be compared with the marginal cost of that additional unit.
The marginal social cost (benefit) is the total cost (benefit) to society as whole for producing one
further unit. It is not only the direct cost (benefit) borne by the producer; it also includes the cost
(benefits) to the external environment and other stakeholders. As a result, the marginal social cost
(benefit) is expressed as follow:
MSC = MPC + MEC
With MSC = marginal social cost
MPC = marginal private cost
MEC = marginal external cost
Social costs or benefits take into account externalities, while private costs/benefits do not. An
externality is a consequence of an economic activity, not transmitted through prices, experienced by a
third party who did not agree to the activity. An externality can either be positive (it is a benefit for the
third party) or negative (it is a cost for the third party). For example, industrial farm animal production
presents a negative externality due to the overuse of antibiotics: it contributes to the increase of the
pool of antibiotic-resistant bacteria. Keeping bees for their honey is a positive externality since bees
actively contribute to the pollination of crops. In the case of pollution, the social cost is generally
higher than the individual cost due to these externalities.
The graph below illustrates the evolution of the cost and benefits to society regarding the level of
abatement. The MSC of abatement is the cost to society as polluters reduce their emissions: reducing
one more unit of pollution is more expensive, thus the MSC is an upward curve. The MSB of
abatement is the social gain of having a cleaner environment; it is the society demand for pollution
abatement. The society is willing to pay for a cleaner environment, but this willingness decreases with
the increasing level of abatement 14. The equilibrium is reached when MSC is equal to MSB. Qeq is the
social optimal quantity of abatement. It is desirable to reduce the emissions as long as the marginal
benefits are higher than the marginal costs.
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14
Callan and Thomas, 2007.
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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Figure 2: the socially optimal level of abatement
3.2.2
The MACC curve
A marginal abatement cost curve represents the relationship between the cost-effectiveness of different
abatement options and the total amount of GHG abated (cf. table 1). It reflects the additional costs of
reducing the last unit of carbon and is upward-sloping: i.e. marginal costs rise with the increase of the
abatement effort.
MACCs can be derived in different ways, either as a histogram or as a curve, as presented in table 1.
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Table 1: the two designs of MACC
The histogram
A
The curve
B
Source: FAO 2011
Source:
http://www.ecn.nl/docs/library/report/2011/o11017.pdf
The histogram assesses the cost and reduction potential
of each single abatement measure
Each bar represents a single mitigation option.

The width of the bar represents the amount of
abatement potential available from the action (in
MtCO2e).

The height of the bar represents the average unit
cost of the action (cost per ton of CO2e saved).

The area (height * width) of the bar represents
the total cost of the action, i.e. how much it
would cost altogether in order to deliver all the
CO2 savings from the action
The curve indicates the cost, usually in $/t CO2-eq,
associated with the last unit (the marginal cost) of
emission abatement (in general in million tons of CO2).
The curve enables us to analyze the cost of the last
abated unit of CO2 for a defined abatement level while
the integral of the abatement cost curve (the area
under the curve) gives us the total abatement costs.
For example here, the point (q,p) represents the
marginal cost, p, of abating an additional unit of carbon
emissions at quantity q. The integral of the area under
the curve (hatched area) represents the total
abatement costs of carbon emission reduction q.
The total width of the MACC shows the total CO2 savings
available from all actions, and the sum of the areas of the
total amount of bars represents the total cost of
abatement for all actions.
This type of MACC representation is easy to understand;
the marginal cost and the mitigation potential can be
unambiguously assigned to one option. We will especially
focus on this type of graph in the rest of the paper.
In both cases, moving along the curve from left to right worsen the cost-effectiveness of low carbon options since
each ton of CO2e mitigated becomes more expensive. Different mitigation options will occupy different positions on
the curve. Some options may be able to reduce emissions and save money (A), other options may reduce more
emissions, but incur a positive cost (B).
Usually, two different approaches are used to build such curves: either an economy-orientated topdown model or an engineering-orientated bottom-up model. The top down analysis is based on a
macro-economic general equilibrium model, providing overall cost to the economy. Top-down curves
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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are preferred for studying macroeconomic and fiscal policies for mitigation purposes. The bottom-up
approach models abatement potential and cost for individual technologies or measures. There are more
useful for studying options that have sectoral and technological implications 15. To be rigorous and
consistent the MACC appraisal has to follow a common recognized methodology, accounting for
AFOLU specificities. The results have to be transparent and comparable to other sectors of activity
(energy, transportation, manufacturing...).
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3.3
Using MACC as a planning tool in agriculture
3.3.1
Relevance of the MACC approach to appraise low carbon options within a
policy
Low carbon growth is an economic growth with a reduced carbon footprint. Nationally Appropriate
Mitigation Actions (NAMAs) may become an interesting path to foster low carbon growth. NAMAs
are voluntary country engagement proposals to the United Nations Framework Convention on Climate
Change (UNFCCC). They consist in a set of government prioritized actions aimed at reducing or
limiting Green House Gas emissions. They are expected to be the main vehicle for mitigation action in
developing countries under a future climate agreement. NAMAs combine a set of actions that are
necessary to facilitate the transition to low-carbon growth for different sectors of the economy,
including agriculture and forestry.
The following approach could allow countries to switch directly from NAMAs to a set of AFOLU
actions assessed and prioritized on the environmental impact, for example via the support from tools
such as EX-ACT, measuring the carbon balance, but also the economical impact, e.g. via MACC. (cf.
figure 3). These actions need to be incorporated in the sector policy and planning framework, with
donor support through project implementation. It would mobilize sector ministries and implementing
agencies from agriculture and forestry and possibly from the ministry of planning.
15
UNFCCC, 2006.
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Figure 3: From NAMAs to low-carbon options in sector planning and
projects
Select AFOLU actions from NAMA Government
engagement
Ensure integration of these actions in AFOLU
Strategies/policies
Feasibility analysis & Localisation of
actions (spatial mapping)
EX-ACT carbon balance
appraisal
Economic appraisal (MACC
Analysis) to compare option
Bringing the action with projectprogramme (Donor/National) funding
Source: FAO TCSP (2011).
3.3.2
Methodology for a MACC assessment in the AFOLU sector
The proposed methodology aims at establishing priorities between AFOLU low carbon options. First,
the options mitigating climate change are identified and chosen. Then, the maximum technical potential
of GHG mitigation is quantified, depending on land use constraints. Finally, the cost of the action is
estimated.
The following provides the required steps for a MACC assessment in the AFOLU sector.
3.3.2.1
Criteria of selection to be considered before selecting low carbon
options to appraise
The MACC approach is not a sufficient instrument to guide policy decisions as it considers only two
dimensions; i) mitigation potential and, ii) costs. Yet, some options’ externalities need to be identified
(cf. table 2). Thus some options could be strictly excluded because they do not allow adaptation, or
have harmful impacts on e.g. poverty reduction, employment, trade-balance.
Finding a quantifiable cross-cutting indicator is difficult and sometimes not compulsory. In such cases,
it is better to justify the reasons why an option was chosen and according to which criteria.
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
The EX Ante Carbon-balance Tool
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Table 2: Example of an externality assessment matrix
Option
Environmental
externality
Economic externality
X
X
X
Option 4
X
X
X
X
Option 5
Option 6
X Too
X many
X
negative
Xexternalities
X
Option 7
X
X
Option 8
X
X
X
X
X
X
X
farmer health
X
X
X
Conflict
farmerpastoralist
Option 3
X
security
X
X
Adaptation to
climate change
Option 2
X
Poverty
reduction
X
Trade Balance
employment
erosion
Water
management
landscape
biodiversity
Option 1
Social externality
X
X
X
X
X
X
X
X
X
X
X
X
X
X
Eliminatory
X externalityX
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
X
If an option presents an exceeding number of negative externalities that are not in line with the national
priorities, it will be excluded from the MACC analysis, e.g. the option in red in the table above.
3.3.2.2
Assessing the carbon balance of AFOLU options
A carbon balance is considered as the difference between the carbon emitted and stored by a proposed
AFOLU option in comparison with a reference scenario (baseline scenario), during a time reference (cf.
figure 4).
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Figure 4: Carbon balance frame of appraisal
M tCO2-eq
Without project
Abatement Potential of
the technology over 20
year
Current
emissions
With project
Time
Year 0
Year 20
According to the UNFCCC, the reference also called “baseline” scenario should be the most plausible
baseline scenario including the most credible options of land use, possible land use changes and main
management practices that could have occurred on the land within the project boundary without the
implementation of the project.
The “with project” and “without project” scenarios have to be developed by local interactive expert
groups. These scenarios aim at predicting the area concerned by Land Use Changes (LUC), changes in
agriculture/breeding practices and the consumption of energy.
It could be relevant to assess the carbon balance of different scenarios and take into account the
adoption rate of the mitigation actions. A calculation for the maximum technical potential can then be
compared with the results of a high, central and medium feasibility scenario. 16 Part 3.3.3.3 explains
more precisely the notion of technical maximum potential and feasibility.
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3.3.2.3
Evaluation of the cost-effectiveness of the option
The step will quantify the cost-effectiveness in terms of USD/t CO2e for each mitigation action. First,
the costs and benefits need to be quantified, as well as the timing of costs and benefits, which enables
to calculate the Net Present Value (NPV).
The NPV is used in capital budgeting to analyze the profitability of an investment or a project. It
represents the difference between the present value of the future cash flows from an investment and the
amount of investment. The present value of the expected cash flows is computed by discounting them
at the required rate of return.
A positive NPV means that the project is profitable, whereas a negative NPV means that the costs are
higher than the benefits.
16
Methodology proposed in the study UK Marginal Abatement Cost Curves for the Agriculture and Land Use, Land-Use
Change and Forestry Sectors out to 2022, with Qualitative Analysis of Options to 2050, SAC Commercial Ltd, November
2008
http://www.theccc.org.uk/pdfs/SAC-CCC;%20UK%20MACC%20for%20ALULUCF;%20Final%20Report%202008-11.pdf
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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Figure 5: Formula to calculate the NPV
Ct = the cash flow the investor receives each year
C0 = the initial investment
R = the discount rate
T = the time (duration of the project)
The costs traditionally used focus on direct technical abatement costs; implementation, capital and
production costs. However, when possible, it is recommended to take into account the other indirect
impacts and hidden costs. 17
16F
The costs and benefits taken into account are the additional costs and revenues due to the project,
compared to a reference situation where nothing is done. Some methodologies (Word Bank, IEA 2009)
use a delta NPV, which is the difference between the NPV of the project and the NPV of the reference
situation. In this case, it is assumed that the reference situation is not a static one, and changes occur,
having impacts on the cost and benefits over time. The formula to calculate the MAC is therefore (NPV
of the project – NPV of the reference situation) / (GHG emissions in the reference situation – GHG
emissions in the situation with the project). This approach is mostly required at the policy level
analysis.
The main issue in this step is the choice of an appropriate discount rate. The matter is tackled in part
3.3.3.4.
Furthermore, the NPV is then divided by the amount of GHG avoided and the duration of the project,
thus giving the average annual cost or gain of abatement for each measure, in USD/t CO2e/year.
With the information on the mitigation potential (t of CO2e abated) and the average cost of each
mitigation measure (USD/t CO2e/year), the MAC curve can be drawn. The next step is the analysis of
the MACC results, and the choice of the most interesting mitigation options for policy makers.
17
The Committee on Climate Change’s methodology and approach to using Marginal Abatement Cost Curves to derive
Domestic Carbon Budgets
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Figure 6: From the economical data of a mitigation action to the marginal
cost of the action


Costs
Benefits
Discount rate


Mitigation potential
of (t CO2e)
Duration (years)
3.3.2.4
NPV
Average annual cost per t of
CO2e abated
Option ranking
The low carbon options can be sorted in the MACC into different options:
 The public cost of the option. It is the factor that is generally used, showing the most cost
efficient option. However this ranking hides the farmers’ willingness to adopt an option, and
therefore the adoption rate could be lower than expected. The public costs illustrate the support
of the government towards the mitigation measure. It includes direct investment for example in
seeds’ development or in tree plantation, fund transfers to help farmers such as subsidiesvoucher for fertilizers, seeds and feed, financing of technical support in the form of extension
service (agricultural adviser), payment of environment services and finally administrative cost,
to manage all the previous investments and financings.
 The farmer interest. The private cost represents the costs and benefits for the farmer: the
expenses for purchasing fertilizers, and supplements feed, increasing labor and the revenues
from a higher yield. Within some low carbon options, the farmer or the micro-agent may lose a
specific income–source by not doing / avoiding a specific option (for instance loosing income
of crops on new deforested area, due to non deforestation). This is accounted as an opportunity
cost for the private operator. Such opportunity costs need to be covered by appropriate
incentives (payment of Environment services, honorarium of forest control-protection, input
voucher) to ensure the low carbon option is implantable and sustainable after project. Such
incentives are accounted as additional incomes for private sector. The farmer interest could be
used to identify the easiest option to be implemented on the field. However, the abatement cost
is always expressed in currency per T of CO2-eq, whereas the farmers would rather be
interested in a benefit in terms of currency per working days or per hectare (depending on the
level of intensification). Therefore it could be worth expressing the benefits from a farmers’
point of view to ensure better option penetration.
 The ratio between public and farmer (also called “Leverage effect”). The factor helps to better
understand the farmer benefit for each dollar spent by public policy. That could be a way to sort
the options regarding their poverty-reduction potential.
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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Figure 7: Final MACC chart integrating both public and private cost
Cost of a t CO2-eq abated
Option 5
Option 4
Option 3
Option 1
t CO2-eq abated
Option 2
Public and Farmer Cost MACC
The MACC presentation of the previous feasible options allows prioritizing them regarding the costeffectiveness of carbon abated and the leverage effect. Once drawn, the MACC is ready for
interpretation (cf. Table 3).
Table 3: Example of MACC interpretation
Option 1
Option 2
Option 3
Comment
Priority
Farmer benefit > Public Cost
2
Option with good leverage effect and great potential
Farmer benefit < Public Cost
1
3
Interesting option for farmer but cost-inefficient regarding the leverage
effect
Option 4
it costs the Farmer to implement this option (avoided deforestation for 4
example but could be implemented with PES (Farmer Cost > Public cost)
Option 5
Farmer cost and Public cost are high
Those options could not be financed at this stage of technology
Long
term?
Regarding public costs, the cost for the government of implementing a specific mitigation action could
be compared with the price of the ton of carbon on the market. It could help identify and choose actions
that can be financed by the carbon market. If the public cost is lower than the current price of one ton
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of CO2e on the market, selling carbon credits from the mitigation option would allow financing it
entirely.
3.3.3
Development of the MACC analysis: points to be aware of
3.3.3.1
Precautions to be taken with the superimposition of two mitigation
options
Sometimes it is not possible to account for several options on the same area since the project
boundaries would not be respected. If two options are implemented on the same area, the user needs to
build a third option for this surface area. However, these carbon potential is not the sum of the two
previous options (option 3 ≠ option 1 + option 2). Figure 8 below explains this situation. This issue is
linked with the one about interactions between measures. If option 1 and 2 are implemented on the
same area, they can interact together. It is necessary to take into account this interference in the MACC
analysis, as explained in part 3.3.3.5.
Figure 8: The need of creating an additional option when several options are
applied on the same area (avoiding double accounting)
Option 1+2 ≤ 100% Area
Option 2
Option 1
Option 1+2 > 100% Area
Option 1
Option 2
Option 1
Option
3
Option 2
Option 1+2+3 ≤ 100% Area
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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15
The land use (LU) change follows the same logic. An area allocated to a new LU could not be used for
an option corresponding to the initial LU.
To follow the EX-ACT methodology, the most representative mitigation potential is the maximum
potential of all selected management practices. The approach is conservative and is supposed to be the
best choice because there is evidence in the literature that certain options are not additive when applied
simultaneously. Thus, the final carbon balance is not the addition of the two previous potentials. With a
conservative approach, only the practice with the best mitigation potential is taken into account.
In some cases different options cannot be split. For example:
 At field scale, the “no tillage-residue management” practice could be implemented only if there
is no residue burning and no grazing.
 At the agro-system scale, there is a need of manure production. Therefore, straw has to be
harvested (excluding no-tillage practice, and implying no fire use), forage have to be produced
(land-use change, or pasture improvement), and livestock better managed.
3.3.3.2
Construction of the baseline scenario
The assumptions for building the baseline scenario are very important. Indeed, depending on the
hypothesis taken into account, the results of carbon balance can be very different.
The baseline scenario should be the most plausible baseline scenario 18 including the most credible
options of land use, possible land use changes and main management practices that could have
occurred on the land within the project boundary, without the implementation of the project.
17F
Currently, there is no consensual precise methodology to build the baseline. The future GHG emissions
are indeed driven by numerous factors such as future economic development, population growth,
international prices, technological development, and so on, thus leading any projection to have more or
less uncertainty. In any case, some criteria’s have to be respected to elaborate the BAU scenario.
Different kind of baseline scenario can be build:
 No change scenario
 Use of past trends to get the future trends
 Use of models and forecasts for the future
The no change scenario is often applied on small scale appraisal for which the project aims at changing
a current “static” situation. It is the simplest way of building the baseline scenario as the current
situation is the well known entry point.
The two other approaches will be used according to the availability of data linked to future trends. The
use of predictive models should be preferred when available. By default, if no projections have been
conducted, the easiest would be to forecast the future by using the past trends.
As a result, the best way to overcome this issue is to compare the results with different baseline
scenarios, and see how the results are impacted by the choice of the baseline scenario. 19
1 8F
18
UNFCCC http://cdm.unfccc.int/UserManagement/FileStorage/W9RY2SX45CMGK3QT16ZFPUED7IBN0V
16
EASYPol Module 116
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3.3.3.3
Choice of the feasible
technical potential
mitigation
potential
against
maximum
The mitigation potential and consequently the total cost of abatement depend on the adoption rate of
the mitigation action. It is also useful to analyze different scenarios according to the level of
penetration. Finally, the maximum technical potential and another degree of feasibility have to be
distinguished.
The Committee on Climate Change, which is an independent body advising the UK Government on
setting and meeting carbon budgets and on preparing for the impacts of climate change, advises to draw
four different MACC:
 Maximum technical potential: the official IPCC definition is «the amount by which it is possible
to reduce GHG emissions by implementing a technology or practice that has already been
demonstrated. There is no specific reference to costs here, only to ‘practical constraints’,
although implicit economic considerations are taken into account in some cases». The
maximum technical potential should reflect a 100% technology implementation. 20
19F
 High feasible potential: it is a percentage of uptake if the government made the measure
mandatory through regulation 21
20F
 Central feasible potential: it represents the likely percentage arising if there were a policy to
subsidise the cost of implementing mitigation measures or penalise emissions 22
21F
 Low feasible potential: it is the level of uptake if the government encourages adoption through
education and information. 23
22F
3.3.3.4
Choice of the discount rate
In order to calculate the abatement cost of one ton of CO2e, the Net Present Value (NPV) of the action,
which is a mean to measure the profitability or the cost of a project, has to be known.
The choice of the discount rate, in order to calculate the NPV, can have significant implications on the
cost effective potential for abatement. The discount rate is the minimum level of return on investment a
company or a government deems acceptable.
The higher the discount rate, the higher the ‘repayment’ needs to be 24. For example a low-tillage
equipment lasting 10 years will have to generate benefits, e.g. yield increase and fertilizer savings,
worth almost 20% more when using a 7% discount rate compared to a 3.5% discount rate. The
treatment of discount rates has significant differences to the cost effectiveness of abatement options.
2 3F
Two types of discount rates are usually used referring to different related concepts:
19
FAO 2011, Readers can find more guidance on the construction of a baseline scenario in the EX-ACT paper Main
Recommendations for the Elaboration of the Baseline Scenario.
http://www.fao.org/fileadmin/templates/ex_act/pdf/Policy_briefs/Building_the_baseline_draft.pdf
20
CCC, 2008.
MacLeod et al, 2010.
22
MacLeod et al, 2010.
23
MacLeod et al, 2010.
24
CCC, 2008.
21
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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17
 The private rate reflects the cost of capital, using a private weighted average cost of capital
(WACC). It represents the cost of a loan, foregone income from an alternative investment or
transaction costs. That kind of discount rate could be used to describe farmers’ preference for
the present time. Usually, a 10% discount rate is used, measuring the cost faced by private
individuals when making investment decisions.
 The social discount rate provides an estimate of the rate for which society trades off the future
and the present. It reflects society’s preference over time, i.e. present benefits and subsequent
costs. The lower discount rate can be 3.5% for example. The BERD (2010) states that “Most
MAC-curves calculate the cost of carbon-reducing investment projects from the perspective of a
social planner, where costs are engineering resource costs, discount rates reflect the
government cost of borrowing and investment risks are ignored (rather minimized). These
models produce a very optimistic picture of a vast abatement potential that could be realised at
no cost or even at a profit to society. However, because many of the abatement opportunities
deemed to be money-saving are unlikely to be financially viable in the marketplace, societalabatement cost curves have been viewed with scepticism by project developers and financial
institutions.” 25
24F
In reality, abatement is not achieved by governments, but by a myriad of private and public investors
who have different perspectives from social planners and who pay taxes and receive subsidies (BERD,
2010). It is why a type of hybrid discount rate can be used, as suggested by the CCC (2008), where the
social discount rate also includes costs of capital. 26
25F
Yet, another solution has been recommended: to use declining discount rates applied to environmental
benefits that will persist far into the future. For example, Weitzman 27 (2001) recommends declining
discount rate scale as follows. Use a discount rate of 4% for the first five years, 3% for the sixth year
until year 25; 2% for years 26 through 75 years.
26F
3.3.3.5
Interaction between two options
An abatement measure can be applied on its own, i.e. stand alone, or in combination with other
measures 28. In the second case, measures are likely to interact and their abatement potential and cost
effectiveness may change For example, if farmers in developing countries increase the productivity of
their crops, but use more fertilizers, it will increase the extent to which the N fertilizer can be reduced
but at the same time it can decrease the cost of forest preservation, since there will be less deforestation
due to higher yields (figure 9).
27 F
25
BERD, Special Report on climate change, Effective policies to induce mitigation, 2010
The Committee on Climate Change’s methodology and approach to using Marginal Abatement Cost Curves to derive
Domestic Carbon Budgets
27
Weitzman, M.L. (2001) “Gamma Discounting, “American Economic Review 91(1), 260-271.
28
MacLeod and al, 2010.
26
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EASYPol Module 116
Analytical Tools
These interactions have to be accounted on the final MACC chart, but the message of priority could be
distorted.
Figure 9: The impact of interaction on the final decision.
Option 1: increasing crops’ productivity by using more fertilizers and improved seeds presents an
abatement cost of 10 USD/tCO2-eq.
Option 2: reducing deforestation presents an abatement cost of 15 USD/ tCO2-eq.
Therefore option 1 should be chosen in priority.
Option 1 may have an impact on option 2. With higher yields, the population won’t need more arable
land to produce their necessary quantity of corn, maize, sorghum ...The slash and burn practices are
supposed to decrease, resulting in less forest areas cleared to cultivate crops. As a result, the action of
protecting the forest would become cheaper, reaching 5 USD/t CO2e instead of 15 USD, since a
percentage of the forest is not threaten anymore due to the crops ‘intensification.
If options are sorted again by cost-effectiveness, the option 2 could be chosen in priority. In this case,
the message conveyed is false and hazardous, i.e. option 2 is under evaluated if option 1 is not applied.
To jeopardize the risk of interactions, the ranking of options have to be conducted before the cost
interaction appraisal, and the interactions need to be clearly notified on the MACC chart.
Each time a practice is implemented, the abatement rate and cost of the remaining measures have to be
recalculated. Failing to take into account interactions between measures is likely to lead to significant
double-counting and over-estimation of the overall abatement potential. 29
28 F
3.3.3.6
Time dimension in long-term policy planning
To account for dynamic processes, a dynamic MACC can be built. Such work is useful for systems that
change in time. For example, thanks to technology evolution, it is expected that option costs would
decrease in the long-term, via commodity prices, R&D, investment, learning effects, economies of
scale and indirect effects of non GHG policies. At the same time, as systems become more efficient
overtime, the total mitigation potential will decline, resulting in higher costs per t CO2e. Therefore,
while MACCs are useful tools for assessing the current cost-effectiveness of different mitigation
practices, policy formulation should include analysis of the measures cost dynamics, i.e. how the cost
effectiveness might change through time 30.
29F
The current cost-ineffectiveness option, i.e. options on the right side of a MACC, could become
interesting in long term policy as the cost of implementation and the benefit might change due to
technology improvement.
29
MacLeod et al, 2010. Developing green house gas marginal abatement cost curves for agricultural emissions from crops
and soils in the UK, M. MacLeod and al., Agricultural Systems, Volume 103, Issue4, May 2010, p.198-209
http://www.sciencedirect.com/science/article/pii/S0308521X1000003X
30
MacLeod et al, 2010.
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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19
For each option a time-based curve could be drawn to estimate the time when the cost effectiveness
will be reached (cf. figure 10).
Figure 10: Option cost evolution
As an example, option 1, for example increasing crops’ productivity, seems to be increasingly effective
compared to option 2, e.g. reforestation, since the cost at the beginning is lower. However, if option 2
belongs to a dynamic sector, the cost could decrease rapidly and become cheaper than option 1.
The assumption taken to foresee the cost’s evolution is very important before concluding which option
needs public expenditure.
Some options may have irreversible impacts and present opportunity window to be implemented on
short delay (avoided deforestation, exploitation of wetlands).
3.3.3.7
Non recognition of ancillary benefits
MAC curves usually only concentrate on carbon emission abatement, thus attributing all of the costs
associated with the abatement to carbon emission reductions. Ancillary costs or benefits are not
included, even if the reduction in CO2 emissions generates co-benefits on animal welfare, energy
consumption, diffuse water pollution or air pollution. These co-benefits are difficult to quantify as they
involve different spatial and temporal scales 31.
30 F
Such a limit needs to be taken into consideration when choosing low carbon options to build an
agricultural policy.
Figure 16 below sums up the four steps to build a marginal abatement cost curve in the agricultural
sector, and points out the limits to take into account before making a decision with the MACC results.
31
Kesicki, 2010.
20
EASYPol Module 116
Analytical Tools
Figure 11: Methodology to build a MAC curve for AFOLU mitigation option
Step
/
Associated focus of attention (limits) / Consequences
The decision will depend on:


The mitigation potential of each measure
(t CO2e)
The average cost of avoided emissions
for each measure ($/T CO2e)

Funds available for the financing (total

cost per measure $)
Government objectives (total mitigation
to achieve)
Cost of a t CO2eq abated
Cumulative t CO2eq
abated
in
comparison to a
without scenario
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4
21
CONCRETE APPLICATION OF THE MACC WITHIN THE EX-ACT TOOL
4.1
Carbon balance appraisal with EX-ACT
EX-ACT is a tool developed by FAO and aimed at providing ex-ante estimates of the impact of
agriculture and forestry development projects on GHG emissions and C sequestration, indicating its
effects on the C-balance 32, which is selected as an indicator of the mitigation potential of the project 33.
It is capable of covering the range of projects relevant for the land use, land use change and forestry
(LULUCF) sector. It can compute the C-balance by comparing two scenarios: “without project”
(i.e. the “Business As Usual” or “Baseline”) and “with project”. The main output of the tool consists of
the C-balance resulting from the difference between these two alternative scenarios (figure 12).
31F
32F
The model takes into account both the implementation phase of the project (i.e. the active phase of the
project commonly corresponding to the investment phase), and the so called “capitalization phase”
(i.e. a period where project benefits are still occurring as a consequence of the activities performed
during the implementation phase). Usually, the sum of the implementation and capitalization phases is
set at 20 years. EX-ACT was designed to work at a project level but it can easily be up-scaled at
program/sector or national level 34.
33F
Figure 12: Quantifying C-balance “with” and “without project” using EX-ACT
Source: Bernoux et al. 2010
32
C-balance = GHG emissions - C sequestered above and below ground.
EX-ACT 2010.
34
Bernoux et al. 2010.
33
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EASYPol Module 116
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EX-ACT measures C stocks and stock changes per unit of land, as well as Methane (CH4) and Nitrous
Oxide (N2O) emissions expressing its results in ton of Carbon Dioxide equivalent per hectare
(t CO2e.ha-1) and in ton of Carbon Dioxide equivalent per year (t CO2e.year-1).
4.2
Linking EX-ACT results with MACC design
The low carbon options planned by project designers are occasionally crosscutting the EX-ACT
modules. The modular approach prevents us from clearly seeing the carbon balance of each adopted
option.
Figure 13: How to manage the complexity
A MACC enables to manage these two dimensions of complexity. The curves could be presented to
businesses or public policy makers to compare the results of different investments in terms of carbon
storage and benefits.
Figure 14: ... using MACC to synthesize the information
Cost of a t CO2-eq abated
Less efficient option: cost
to be implemented
Cumulative t CO2-eq abated in
comparison to a without scenario
More efficient option: pay
for themselves
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23
For visibility purposes it is recommended to limit the number of options to preserve the MACC chart
visibility. One option can be split into several EX-ACT modules, e.g. annual crop and inputs. It is thus
necessary to carry out a synthesis of the different parts of the general option, linked with their
agronomic feasibility. Each carbon balance provided by the tool needs to be allocated to an option, in
order to match the carbon balance with the MACC potential.
EX-ACT can be enriched to facilitate the consideration of previous examples:
 With the addition of new columns after each description line of EX-ACT module to allocate the
carbon balance to an option type (cf. figure 15-16).
 With an automatic consolidation of all split options to a new EX-ACT “MACC” module (cf.
figure 17)
Figure 15: Examples of allocating various carbon balances to a single option
24
EASYPol Module 116
Analytical Tools
Figure 16: Use of an allocation matrix to allocate a fraction of inputs for each
option when only one line is used to calculate a carbon balance:
Figure 17: “MACC Module” in EX-ACT to consolidate the previous Carbon
balances
= Line 1 & 2 of module annual + 75% line 1 of module input
= Line 3 & 4 of module annual + 25% line 1 of module input
4.3
Example of the Turkey National Climate Change Strategy
4.3.1
Selection of the low carbon options to appraise and calculation of the
mitigation potential
The Turkey National Climate Change Strategy identifies priority activities to be carried out in sectors
for mitigating climate change, as well as urgent measures for adaptation. It runs from 2010 to 2020.
Agriculture is one of the tackled sectors. Data from the official government publication 35 have been
used to do the assessment. When no precise data were available, assumptions have been made, based
on FAO Stat data for 2008. Figure 18 gives the land use in 2008 36 and table 4 the actions planned
within the strategy.
34F
35 F
35
Republic of Turkey – National Climate Change Strategy (2010-2020) – TR Ministry of Environment and Forestry, May
2010, p.11 and 12 http://www.iklim.cob.gov.tr/iklim/Files/Stratejiler/National%20Strategy.pdf
36
FAO Stat.
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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25
Figure 18: Turkey Land Use in 2008
Turkey Land Use, 2008 (in 1000 ha)
forest
11,096
perennial
14,617
other land
26,744
agricultural land
39,122
annual crop
17,296
grassland
2,950
fallow
4,259
Table 4: Mitigation options planned in the Turkish strategy, with the surface
area (or the number of head) concerned, and EX-ACT modules to refer to
Activities
12
EX-ACT
module
Surface area concerned
(in ha or head or t of
inputs)
Grouping in one
mitigation option
“without”
scenario 37
“with”
scenario
traditional annual crops
17,296,000
10,377,600
improved annual crops
(nutrient management,
better agronomic
practices)
-
5,188,800
30%
crops improvement
(seeds, rotation,
nutrient)
1,729,600
10%
promotion of organic
and no-tillage farming
(tillage, manure)
36F
Annual
organic & no tillage
traditional grassland
improved grassland
Grass
traditional paddy rice
improved paddy rice
(irrigation)
37
% change
(in blue
when it is an
assumption)
Irrigated
rice
FAO Stat http://faostat.fao.org/default.aspx
2,950,000
2,212,500
-
737,500
99,493
74,620
-
24,873
25%
25%
grassland
improvement
rice irrigation
improvement
26
EASYPol Module 116
Analytical Tools
Activities
EX-ACT
module
12
Surface area concerned
(in ha or head or t of
inputs)
% change
(in blue
when it is an
assumption)
Grouping in one
mitigation option
“without”
scenario 37
“with”
scenario
14,104,757
11,121,505
increase
2%/year
-
2,224,301
20%
-
2,300,000
fallow
4,259,000
1,959,000
total less fertilizers
(nutrient management)
2,059,815
1,647,852
20%
Crops improvement
(90%) and organic
farming (10%)
33,914
40,697
20%
Afforestation (21%)
and organic farming
(79%)
36F
stabilization of livestock
better feeding practices
for cattle
Afforestation (on fallow
and degraded lands)
Livestock
A-R
livestock
management
afforestation
Inputs
Increased use of
pesticides
After having reallocated the emissions of each activity to the appropriate option, the final carbon
balance of the Turkish National Strategy is as follows (table 3). It is important to understand that the
result depends on the baseline scenario and assumptions. Interactions between actions have not been
studied in this example.
Table 5: Carbon balance for the Turkey National Climate Change Strategy
Options
Mitigation potential t CO2e
crops improvement
-
50,251,527
promotion of organic and no-tillage
farming
-
39,157,006
livestock management
-
38,418,558
grassland improvement
-
13,666,858
afforestation
-
954,802,921
rice irrigation improvement
-
6,536,546
total
- 1,102,833,415
The afforestation option is the one that avoids the largest part of GHG. (87%)
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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4.3.2
27
Evaluation of the cost effectiveness and analysis of the MACC results
The next step is to calculate the costs of each option as well as its benefits. Data from the literature
have been used, more or less adapted to the Turkish context. Two different analyses could be done
here: either using public cost, i.e. the cost for the government to help and encourage the adoption of the
option, e.g. vouchers to buy concentrates for the animals, bearing the cost of certification for farmers
who want to turn to organic agriculture, free distribution of genetically improved seeds. In the present
case, the available data allow us to study the costs for the farmers, except for the afforestation option,
which is a public cost.
The costs reflect the implementation work, which occurs only once (tree plantation, certification of
organic farms...) or a maintenance work, which is recurrent (nutrient management, no-tillage, use of
pesticides, better feeding practices...).
The benefits have to be known as well in order to calculate the free cash flow and the NPV. An Internal
Rate on Return (IRR) and a payback period can equally be calculated, to enrich the economic analysis.
Most of the benefits directly concern the farmer, e.g. increase in yield, savings on fertilizers’ purchase,
on water use, on fuel (no-till), whilst others are more general, good for both society and farmers like
the fight against erosion.
Different situations have been analyzed to take into account the limits of a MACC assessment, with
interaction between options and discount rate:


A public discount rate of 3.5% versus a private discount rate of 10%, no-interaction
Interaction between options versus no interaction, discount rate of 3.5%
4.3.2.1
Comparison of the MACC results depending on the discount rate
Public discount rate of 3.5%
Comment: the rice irrigation improvement is the most
cost-effective action with an average price of -15 $/t
CO2e (so it is a profit). Each ton of GHG avoided due
to crops improvement, afforestation and grassland
improvement represents an almost zero cost option
(prices between -1 and -0.1 $/t). The activities
planned within the livestock management option are
the most expensive, with an average price of 45 $/t
CO2e.
U
U
The afforestation provides most of the mitigation
potential.
Regarding the total cost of mitigation (mitigation
potential * average cost per t CO2e), the promotion of
organic and no-tillage farming is the cheapest action,
followed by rice irrigation. Even if rice irrigation has a
more profitable cost per t of CO2e, its limited
mitigation potential explains why it is not the more
profitable option in globally. Once again, the livestock
management is the more expensive option.
The public discount rate gives an optimistic view on
the abatement potential that can be achieved at profits
for society through rice irrigation improvement and
organic farming development.
28
EASYPol Module 116
Analytical Tools
Private discount rate of 10%
Comment : the option ranking remains the same as
with a 3.5% discount rate: rice irrigation improvement
is the cheapest option with an average price of -8$/t
CO2e while livestock management is still the most
expensive (24$/t).
U
U
The private discount rate gives less optimistic value for
rice and organic option. However they are still
profitable activities but with a less pessimistic value for
livestock.
Private discount rate tends to minimize both the
benefits (for negative marginal costs) and the costs
(for positive marginal costs) of a mitigation option.
The choice of the discount rate will depend on which point of view the MACC analysis is done. If it is
to evaluate the mitigation potential and cost of a farm or an agricultural cooperative, the private
discount rate is the most appropriate. If the MACC is done from the point of view of a government, it
would be more accurate to use a hybrid discount rate that includes both public and private criteria.
Indeed, the interaction between both actors, the government and the private sector, is an important
point in the definition of mitigation policies.
4.3.2.2
Comparison of the MACC results depending on the interactions
between options
The implementation of the grassland improvements will decrease the cost of the livestock management
(see figure 19). Indeed, better quality forage will be produced, richer in N, enabling to reduce the
amount of concentrate given to the cattle within the better feeding practices. Limiting the increase in
cattle number will also have impacts on the grassland improvement option. It will reduce the
implementation cost of grassland (no additional animals can be bought since we want to stabilize the
cattle size) and increase the benefits (the meat demand will exceed the supply, leading to an increase in
the price of the meat).
Figure 19: Interactions between grass improvement and livestock management
 implementation cost,
 benefits (meat sold at a higher
price)
Grassland improvement
Livestock management
 quantity of concentrates
needed, thus  the cost of better
feeding practices
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
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29
Without interactions
Comment : grassland
improvement almost costs
nothing (-1.1 $/t CO2e) while
the livestock management costs
45$/t.
U
With interactions
U
Comment : the livestock
measure now only costs 18$/t
CO2e, and the grassland
improvement option is a bit
more profitable (-1.4$/t)
U
U
However, in our case, it does
not change the option ranking.
But it could convince the
government to consider
financing the livestock
management activity in parallel
with grassland improvement.
5
CONCLUSION
The AFOLU sector is a major actor to minimize the effects of climate change. Indeed, it has a
pronounced mitigation potential, especially with regards to the carbon storage in agricultural soils and
biomass. However, even if a wide range of mitigation options are known, there is still a reluctance to
implement them at a large scale. One of the reasons is the lack of economic and financial background
of such actions.
Marginal Abatement Cost Curves have been developed since the end of the 90s’. They are being
increasingly used in different economic sectors, as a decision making tool for policy makers or large
companies. The key challenge is to find ways of managing the complexity of the agricultural sector in
ways that enables the development of MACC without sacrificing the validity of the results. The present
30
EASYPol Module 116
Analytical Tools
guidelines particularly provide advice on the methodology to calculate the MACC of an agricultural
project. It also highlights the limits and the points to be aware of before taking the results of the MACC
for granted, such as the choice of the discount rate, the recognition of interactions between mitigation
options and the narrow window of projection. The approach requires further development, for example
the incorporation of ancillary costs and benefits of GHG mitigation into the calculation of the cost
effectiveness or the time dimension.
MACC is one tool to help decision makers, but it must not be the only one. Complementary
economical tools, risk management tools, marginal welfare costs, vulnerability assessments and others
biological and production indicators must complete the tool kit in order to have a global study which
takes into account all the parameters and possible effects of a policy.
6
READERS’ NOTES
6.1
Links to other related EASYPol modules
EX-ante Carbon-Balance Tool : Software
U
http://www.fao.org/docs/up/easypol/873/ex-act_version_3-2_april_2011_101sp.xls
EX-ante Carbon-Balance Tool : Technical Guidelines
U
http://www.fao.org/docs/up/easypol/780/ex-act-tech-guidelines_101en.pdf
EX-ante Carbon-Balance Tool : Brochure
U
http://www.fao.org/docs/up/easypol/780/ex-act_flyer_101en.pdf
Investment Planning for Rural
Development - EX-Ante Carbon-Balance Appraisal of Investment Projects
See all EX-ACT work in EASYPol under the Resource package,
7
U
FUTHER READING
ADAS UK Ltd, May 2010. RMP/5142 Analysis of Policy Instruments for Reducing Greenhouse Gas
Emissions from Agriculture, Forestry and Land Management, UK.
http://archive.defra.gov.uk/foodfarm/landmanage/climate/documents/climate-ag-instruments.pdf
CCC, 2008, Building a Low-Carbon Economy, December 2008, The UK’s contribution to tackling
climate change, Committee on Climate Change, UK.
http://www.theccc.org.uk/reports/building-a-low-carbon-economy
Calla S, Thomas JM, 2007, Environmental Economics & Management: Theory, Policy and
Application, Cengage Learning, Florence, USA.
Cunningham R, February 2009, Discount Rates for Environmental Benefits Occurring in the FarDistant Future, Independent Economic Advisers, Washington DC, USA.
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Davidson M.D, Van Essen H.P, 10 March 2009, EU Transport GHG: Routes to 2050, Methodological
issues related to assessing cost effectiveness of climate change abatement options.
Using Marginal Abatement Cost Curves to realize the Economic Appraisal of Climate Smart Agriculture Policy Options
The EX Ante Carbon-balance Tool
31
EBRD, Grantham Research Institute on Climate Change and the Environment, 2011, Special Report on
Climate Change, the Low Carbon Transition – Chapter 3: Effective policies to induce mitigation,
European Bank for Reconstruction and Development, UK.
http://www.ebrd.com/pages/research/publications/special/transition_lcarbon.shtml
EBRD, 2010. Special Report on Climate Change, Effective Policies to Induce Mitigation, European
Bank for Reconstruction and Development, UK.
http://www.ebrd.com/downloads/research/transition/trsp.pdf
FAO, 2011. Main Recommendations for the Elaboration of the Baseline Scenario - Building the
“Without Project” Scenario within the EX-ACT Tool, EASYPol mimeo.
http://www.fao.org/fileadmin/templates/ex_act/pdf/Policy_briefs/Building_the_baseline_draft.pdf
Hogg D, Baddeley A, Ballinger A, Elliott T, December 2008. Development of Marginal Abatement
Cost Curves for the Waste Sector, Report for Committee on Climate Change, Defra and
Environment Agency.
http://www.theccc.org.uk/pdfs/Eunomia%20Waste%20MACCs%20Report%20Final.pdf
IEA, 2009, Methodology for Calculating Electricity and Heat Marginal Abatement Cost Curves
(MACC), World Energy Outlook 2009, International Energy Agency, Paris, France.
http://www.worldenergyoutlook.org/docs/weo2009/weo2009_es_italian.pdf
Kenya National Advisory Committee for the DFID, November 2009, Opportunities for Low Carbon
Growth in Kenya, Version 2, 23/11/2009
http://static.weadapt.org/knowledge-base/files/758/4e25a35715cf15B(1)-kenya-low-carbon-growthassessment-v4-summary.pdf
Kesicki F., 2010, Marginal Abatement Cost Curves for Policy Making – Expert-Based vs. Model
Derived Curves, Energy Institute, University College London, UK.
http://www.homepages.ucl.ac.uk/~ucft347/Kesicki_MACC.pdf
Kiuila O, Rutherford T.F, 2011, Approximation of Marginal Abatement Cost Curve, Working Papers
No. 12/2011 (52), University of Warsaw Faculty of Economic Sciences, Warsaw, Poland.
http://www.wne.uw.edu.pl/inf/wyd/WP/WNE_WP52.pdf
MacLeod and al. February 2010, Agricultural Systems 103 (2010) 198–209, Developing Greenhouse
Gas Marginal Abatement Cost Curves for Agricultural Emissions from Crops and Soils in the UK
McKinsey & Company, 2009, Pathways to a Low-Carbon Economy, Version 2 of the Global Green
House Gas Abatement Cost Curve.
Moran and al., July 2010, Marginal Abatement Cost Curves for UK Agricultural Greenhouse Gas
Emissions. Journal of Agricultural Economics doi: 10.1111/j.1477-9552.2010.00268.x.
Ministry of Environment and Forestry, 2008. General Directorate of Afforestation and Erosion
Control, MoEF, Republic of Turkey,
SAC Commercial Ltd, November 2008, UK Marginal Abatement Cost Curves for the Agriculture and
Land Use, Land-Use Change and Forestry Sectors out to 2022, with Qualitative Analysis of
Options to 2050 - Final Report to the Committee on Climate Change, Edinburgh, UK.
http://www.theccc.org.uk/pdfs/SACCCC;%20UK%20MACC%20for%20ALULUCF;%20Final%20Report%202008-11.pdf
Smith P. and al., Philosophical Transactions of the Royal Society, 27 February 2008 vol. 363 no. 1492
789-813, Greenhouse Gas Mitigation in Agriculture, The Royal Society, London, UK.
http://rstb.royalsocietypublishing.org/content/363/1492/789.abstract
32
EASYPol Module 116
Analytical Tools
Spencer, C. January 2008, Building a UK Transport Supply-Side Marginal Abatement Cost Curve, The
Committee on Climate Change Secretariat
http://www.theccc.org.uk/other_docs/Tech%20paper%20supply%20side%20FINAL.pdf
TR Ministry of Environment and Forestry, May 2010, Republic of Turkey – National Climate Change
Strategy (2010-2020) p.11 and 12, Ankara, Turkey.
http://www2.dsi.gov.tr/iklim/dokumanlar/national_climate_change_strategy.pdf
UNFCCC/CCNUCC, Clean Development Mechanism Form for Proposed New Baseline and
Monitoring Methodology for A/R CDM Project Activities (CDM-AR-NM) (Version 04)
http://cdm.unfccc.int/Reference/PDDs_Forms/Methodologies/methAR_form10_v04.pdf
UNFCCC, May 2006, Training Handbook on Mitigation Assessment for Non-Annex I Parties
http://www.preventionweb.net/english/professional/publications/v.php?id=2766
Weitzman, M.L., 2001. Gamma Discounting, American Economic Review 91(1), 260-271
Wetzelaer B.J.H.W., Van der Linden N.H., Groenenberg H., De Coninck H.C., ECN-E--06-060, GHG
Marginal Abatement Cost curves for the Non-Annex I Region, Energy Research Centre of the
Netherlands
ftp://nrg-nl.com/pub/www/library/report/2006/e06060.pdf
Wreford A, Moran D. and Adger N., 2010. Climate Change in Agriculture – Impacts, Adaptation and
Mitigation OECD publishing, Paris, France.
http://www.oecd.org/document/18/0,3746,en_21571361_43893445_44437010_1_1_1_1,00.html